DE60126888T2 - RADIO COMMUNICATION SYSTEM - Google Patents

Abstract

A radio communication system has a random access channel for the transmission of data ( 214 ) from a secondary station to a primary station. Such a channel is intended for use by secondary stations having data ( 214 ) to transmit to a primary station while not actually engaged in a call. By enabling access requests ( 202 ) to be transmitted with a greater range of possible signatures, a much greater number of degrees of freedom is available to a secondary station requesting access to a random access channel. This enables significantly improved efficiency of resource allocation by increasing the amount of information transmitted to the primary station by the access request ( 202 ).

Description

technical environment

The The present invention relates to a radio communication system with a random access channel for transfers from a secondary Station to a primary station, and continue on primary and secondary stations for use in such a system and method to operate such a system. Although the present specification is a System with particular reference to the emerging universal Mobile Telecommunication System (UMTS) describes, of course, that the described procedures are equally for use in other mobile radio systems are applicable. In this specification, the term "random Access Packet Channel " the logical channel on which random access packet transfers take place, which typically consists of a number of individual physical channels would exist.

background to the state of the art

One System, primary and secondary Stations and a method according to claim Figures 1, 3, 6 and 11, respectively, are well known in the art. A random Access Channel is a normal component of a radio communication system, which allows a mobile statoin (MS) to send short messages to send a base station (BS). Applications include this Signaling to the BS when the MS is turned on, sending a data packet to the BS if the MS may not be on a conversation involved, and requesting the BS to use a resource assigned by the MS.

In a system where mobile stations often have the need for data packets to send to the BS if they are not actually involved in a conversation It is beneficial to have a random access packet channel To provide properties that are a standard random Access Channel, however, for the transmission of small and medium-sized Packages are provided by a MS to the BS.

at an embodiment such for UMTS developed model stands a number of Random Access Packet Channels for an MS available. A request regarding access to a packet channel resource sent by the MS will be available with one of 16 available Signatures coded. Each signature corresponds to a request of one certain resource needed by the MS, for example one Channel with a specific bitrate. If a suitable resource for Use available the BS allocates it to the requesting MS.

One The problem with such a model is that only one limited amount of information during be transferred to the access procedure can, because the number of available Signatures and channels is limited. This problem reduces the efficiency of resource allocation in the system.

description the invention

A The object of the present invention is to provide a random access packet Creating channels with improved resource allocation.

According to one The first aspect of the present invention provides a radio communication system. comprising: a Random Access Channel for transmissions from a secondary Station to a primary Station, with the secondary Station Means for requesting assignment of a random access channel Resource by transfer an access preamble includes, which is encoded with a first signature, which consists of a first Set of signatures selected was, and where the primary Station means for receiving the access preamble comprises the first Determine the signature and transfer an access acknowledgment, which is coded with a second signature, which consists of a second Set of signatures selected and indicates whether the requested resource is available, wherein the choice of the first signature related to further information to the request for allocation of resources and supplies each signature of the second set of a plurality of signatures in corresponds to the first sentence.

According to a second aspect of the present invention there is provided a primary station for use in a radio communication system having a random access channel for transmissions from a secondary station to the primary station, in which means are provided to receive an access preamble sent by the secondary station, encoded with a first signature selected from a first set of signatures to determine the first signature, to determine from the access preamble which random access channel resource the secondary station desires to allocate and to send an access acknowledgment, the is encoded with a second signature selected from a second set of signatures and indicates whether the requested resource is available, the selection of the first signature providing further information relating to the resource allocation request and wherein each signature of the second Set of a variety of signatures in the first sentence corresponds.

According to one Third aspect of the present invention is a secondary station for use in a radio communication system with a random access Channel for transfers to a primary Station created in the means provided for an assignment to request a random access channel resource by transmitting an access preamble, which is coded with a first signature, which consists of a first Set of signatures selected and to receive an access acknowledgment with a coded second signature, which consists of a second set of Signatures selected and indicates whether the requested resource is available, wherein the choice of the first signature related to further information to the request for allocation of resources and supplies each signature of the second set of a plurality of signatures in corresponds to the first sentence.

According to one Fourth aspect of the present invention is a method for Operation of a radio communication system with a random access Channel for transfers from a secondary Station to a primary Station, the method comprising: the secondary station requests the assignment of a Random Access Channel resource by transfer an access preamble which is coded with a first signature, which consists of a first set of signatures was selected; and the primary station receives the access preamble, determines the first signature and transmits one Access acknowledgment, which is coded with a second signature, which has been selected from a second set of signatures and indicates whether the requested resource is available, wherein the choice of the first signature related to further information to the request for allocation of resources and supplies each signature of the second set of a plurality of signatures in the first sentence corresponds.

Short description the drawing

embodiments The present invention will be exemplified below With reference to the accompanying drawings. Show it:

1 a schematic block diagram of a radio communication system;

2 a basic random access channel model;

3 an extended random access channel model in which the transmission time of the preamble and the contra-pruning preambles may be offset;

4 FIG. 3 is a flowchart illustrating a method of attempting access to a random access packet channel using time offsets. FIG.

In The drawings are consistent features denoted by the same reference numerals.

Types to execution the invention

Referring to 1 a radio communication system comprises a primary station (BS) 100 and a variety of secondary stations (MS) 110 , The BS 100 includes a microcontroller (μC) 102 , Transceiver means (Tx / Rx) 104 using antennae means 106 connected, power control means (PC) 107 for changing the transmission power level, and connecting means 108 for the connection to the fixed network or another suitable network. Every ms 110 includes a microcontroller (μC) 112 , Transceiver means (Tx / Rx) 114 using antennae means 116 connected, and power control means (PC) 118 for changing the transmission power level. The communication from the BS 100 to the MS 110 takes place on a downlink channel 122 while the communication from the MS 110 to the BS 100 on an uplink channel 124 he follows.

2 shows a basic model for a random access packet channel that operates in a frequency duplexing system, where the uplink channel 124 over the downlink channel 122 is drawn. In an access phase, the MS sends 110 first in a given access slot at a low power level a preamble (P) 202 which is coded with one of 16 possible signatures. A signature is a signal characterized in that its scrambling code and channelization code are modulated with a specific bit sequence. A set of mutually orthogonal signatures can be obtained by defining a set of mutually orthogonal bit sequences for modulation. A different set of signatures can thus be obtained by changing the scrambling code or the channelization code (ie the physical channel) or by using a different set of mutually orthogonal bit sequences. At the in 2 The basic system shown is a one-to-one mapping between the preamble signature and the acknowledgment ( 206 ), so that the receipt of an acknowledgment by the MS 110 clearly determines which signature is acknowledged. Although the present specification refers to sets of 16 signatures, in other implementations sets are used with a different number of signatures.

Each of the available signatures is mapped to a single bit rate for the packet channel. The set of available signatures, and mappings between signatures and bit rates, may be specified or routinely provided by the BS 100 be broadcast. The MS 110 chooses to encode the preamble 202 a signature that matches its required bitrate. If more than one signature is available that matches the required bit rate, the MS dials 110 a signature at random. If the BS 100 has received the preamble and correctly decoded, it sends a preamble acknowledgment (PA) 206 , In the in 2 Example shown after the transmission of the first preamble 202 no acknowledgment in the slot provided for this purpose 204 (which could, for example, have a length of 1 ms). The MS 110 therefore sends another preamble 202 at a higher power level. This is from the BS 100 received and decoded, and the BS 100 sends an acknowledgment 206 and ends the access phase.

As well as the acknowledgment 206 the MS 110 informed that their preamble 202 it may be positive to signal that the requested resource is available, or negative to signal that it is in use and the MS 110 access is denied. A negative acknowledgment (NACK) may be issued by the BS 100 can be specified by inverting the phase of the signature (relative to a reference or pilot signal). Alternatively, some of the BS 100 signatures used for the acknowledgment can also be used as NACK.

The BS 100 will only send a single acknowledgment for each access slot, but many have preambles 202 Posted. A basis for the selection could be the preamble received with the highest performance 202 to acknowledge. The initial power level at which an MS 110 the preamble 202 is typically transmitted through the MS 110 determined by means of an open power control loop, so that an MS 110 compared to another MS 110 who are closer to the BS 100 is not disadvantaged. If more than a preamble 202 was sent, but each preamble was coded with a different signature, every ms 110 know if their preamble 202 was received correctly or not. However, it is possible that more than one MS 110 has chosen the same signature and therefore believes that its preamble 202 was received. If any of these mobile stations 110 starting to send their data will cause a collision and the data will probably not be received correctly.

To reduce the likelihood of this, the transmission of an acknowledgment can 206 that indicated that the requested resource is available to follow a contention cleanup phase. Every ms 110 containing a preamble 202 which is coded with a signature that is the one sent by the BS 100 acknowledged, now sends another contention-fixing preamble (CP) 208 , This preamble 208 is coded with a signature randomly selected from another set of 16 possible signatures. This sentence may differ from that for the access preamble 202 Alternatively, the set used may be differentiated (by changing either the set of modulating bit sequences, the scrambling code, or the channelization code), or the set of signatures may alternatively be shared by the access and contention resolution phases. The BS 100 then gives a contention adjustment acknowledgment (CA) 210 out, that of the chosen preamble 208 corresponds, for example, the one that was received with the highest performance, the acknowledgment 210 the MS 110 able to send their data. If more than one MS 110 the same access preamble 202 Therefore, the likelihood is that even the same competition pruning preamble 208 is chosen, small. Optionally, a channel assignment message may be sent at substantially the same time as the contention adjustment acknowledgment 210 , or even as part of the acknowledgment 210 as described in our co-pending International Patent Application PCT / EP00 / 06988 (our mark PHGB000003).

After this rival phase, the BS begins 100 the transmission of a Physical Control CHannel (PCCH) 212 that includes power control information to the MS 110 to adjust their transmit power as needed, and the MS 110 sends one or more data packets (PKT) 214 on the associated packet channel, ie, normally on a different physical channel than those used for preamble transmission. The PCCH 212 can be simultaneous with the transmission of the data 214 begin or advance so far that a closed-loop power control can be performed before the data is sent.

A particular problem with the basic model described above is that the efficiency of resource allocation is limited by the number of accessibility preambles 202 available choices. For example, in one embodiment of the model for UMTS, 16 signatures and 12 random access sub-channels are available, so that in total 196 Degrees of freedom result. This problem is in egg A system according to the invention is solved by defining a larger set of signatures which may have low cross-correlations rather than being strictly orthogonal. Such a set of signatures could be defined by modifying the bit sequences used to define the signatures, or using different scrambling codes, or by a combination of both. To avoid the need to allocate a larger number of downlink channelization codes, in 2 in response to each signature from a defined set of preamble signatures, the same acknowledgment ( 206 ) be transmitted. This may increase the likelihood of collisions, but this would normally be an acceptable disadvantage compared to the other benefits of the system.

The Availability significantly more degrees of freedom allows a much more efficient resource allocation. In the case of channel assignment enabled for example, more bitrates.

• • als eine Anforderung einer bestimmten Bitrate;
• • als eine Anforderung einer bestimmten Zugriffsklasse (mit zugehöriger Priorität);
• • als eine Anforderung zusätzlicher Ressourcen (z.B. ein gemeinsam genutzter Downlink-Kanal);
• • zur Angabe der Priorität der Nachricht;
• • zur Angabe der Länge (oder der minimalen oder maximalen Länge) des zu sendenden Pakets;
• • zur Verwendung durch eine bestimmte MS 110; und
• • zur Verwendung durch Mobilstationen 110, die eine Nachricht aus einem Satz Nachrichten einer gemeinsamen höheren Schicht benutzen.

A system according to the invention can use the significantly greater number of degrees of freedom in different ways. Possible assignments for any combination of signature, channel, and non-zero time offset include the following (either individually or in combination):

• As a request for a particular bit rate;
• As a request for a particular access class (with associated priority);
• As a request for additional resources (eg, a shared downlink channel);
• • to indicate the priority of the message;
• • to specify the length (or the minimum or maximum length) of the packet to be sent;
• • for use by a specific MS 110 ; and
• • for use by mobile stations 110 who use a message from a set of messages of a common higher layer.

Some of these allocations could increase the amount of information a higher layer has in the data packet 214 be absorbed. For example, if a particular MS 110 the exclusive use of a subset of the possible uplink signals is their identity of the BS 100 automatically known and does not need in the data packet 214 to be included. Such overhead reduction in packet transmission could be particularly useful for low data rate applications. The same principle could be applied to other shared elements of higher layer information. Other assignments could improve the responsiveness of the system. Specifying the minimum length of a packet to be sent offsets the BS 100 for example, capable of performing an ARQ (Automatic Repeat reQuest) to the MS 110 if it does not receive at least the specified minimum length. Specifying the maximum length of a packet may be the BS 100 enable them to improve their planned resource allocation.

3 shows how the set of possible signatures can be extended by introducing different time offsets. The time of transmission of the access preamble 202 can be _off at T _off in terms of the limit 302 the access slot (itself relative to the BS 100 transmitted time signals is defined). The access preamble 202 and the competition cleanup preamble 208 Both include 4096 chips, while the length of the access slot 5120 Chips is. By allowing time offsets T _off of multiples of the 256 chips, up to 19 different values of T _off other than zero are possible, without introducing an ambiguity about which slot is the preamble 202 . 208 contains. If T _off = 0, the behavior of the system is identical to that of a system without the possibility of time offsets.

The time offset T _off moves the transmission time of the preambles 202 . 208 preferably, since any delay in its transmission could mean that the BS 100 is unable to timely recognize the preamble in order to acknowledge access in an appropriate time slot 206 transferred to.

The time offset for the contra-prudential preamble 208 is preferably the same as that for the access preamble 202 so the BS 100 the two preambles 202 . 208 easy than from the same MS 100 coming can identify.

It is preferable that there are no time offsets in the downlink channels 122 gives, so that the acknowledgment 206 an access preamble 202 regardless of the time offset used is the same. This makes it possible to clean up collisions between transmission with and without offset during the contention-cleaning phase. The use of skews has the further advantage that the number of different signals available for use during the contention-cleanup phase can be increased, thereby reducing the probability of uncleared collisions.

As a variant to the above model, the preamble signature could serve purely as an identifier for the access attempt, while the information relating to the resource allocation request is represented by the time offset and the MS 110 selected sub-channel could be transported.

A flowchart illustrating a method according to the invention with the use of time offsets for an MS 110 is trying to access a packet channel resource is in 4 shown. The procedure begins at step 402 if the MS 110 Has data for transmission on the Random Access Packet Channel. The MS 110 choose first at step 404 a signature corresponding to the required resource, for example the required bitrate. Next, the MS determines 110 at step 406 an appropriate time offset T _off , for example to indicate their identity or the urgency of the data transmission. After selecting these parameters, the MS tries 110 at step 408 to access the packet channel by one or more access preambles 202 and a competition cleanup preamble 208 sends as described above.

In alternative embodiments, not all of the in 3 features required. For example, the uplink power control of the inner loop may not be significant, so PCCH 212 may not exist. The collision cleanup portion may not be significant, in which case the contention cleanup preamble 208 and the acknowledgment 210 may not exist. The consequences of these changes would be a simpler implementation, but then a worse Eb / No performance and an increased probability of collision of message parts must be accepted. In some cases, all the necessary signaling information may possibly be conveyed through the selection of access subchannel and signature, in which case the message part would not be required and could be omitted. As an alternative to selecting the bit rate with reference to the preamble signature, it can be used by the MS 110 determined and by signaling in the message part 214 be specified.

As well, as the present invention in an FDD system as described above Application could find they can also be applied to other types of communication systems. She could for example in a TDMA system (Time Division Multiple Access) provided that the uplink transmissions occur in others Time slots than the downlink transmissions.

The Refer to the above-described embodiments on the packet transfer. The same principles can however, equally be applied to a system in which circuits for data transmission are set up.

Out the reading The present description will be further to those skilled in the art Variations be obvious. Such modifications can be more Features already included in the design, manufacture and the use of radio communication systems as well as components of which are known and which instead of or in addition to the features already described here can be used. The claims were in this application, although in relation to special combinations However, it is understood that the framework the disclosure of the present application also any new features or any new combination of features described herein either explicit or implicit or any generalization this includes independently of whether she refers to the same invention as she does here is described in each claim, and regardless of whether it is any the same technical problems as the present invention triggers or all. The applicants hereby announce that new claims for such Features or combinations of features during the tracking of the present invention Registration or any other derived therefrom application can be formulated.

In In the present specification and claims, the word "on" or "an" in front of an element not the presence of a plurality of such elements. Further close the word "embrace" and its conjugations not the presence of other elements or steps than those mentioned.

applicability in the industry

The The present invention is directed to a number of radio communication systems applicable, for example to the UMTS.

4

• Start Start
• Select signature Select signature
• Select Select offset offset
• Attempt access to try access

Claims (13)

Radio communication system with a Random Access Channel for transmissions from a secondary station ( 110 ) to a primary station ( 100 ), whereby the secondary station ( 110 ) Means for requesting allocation of a random access channel resource by transmitting an access preamble coded with a first signature selected from a first set of signatures, and wherein the primary station ( 100 ) Means for receiving the access preamble to determine the first signature and an access acknowledgment ( 204 . 206 ) transmitted with a second signature co which is selected from a second set of signatures and indicates whether the requested resource is available, the selection of the first signature providing further information relating to the resource allocation request, characterized in that each signature of the second Set of a variety of signatures in the first sentence corresponds. System according to claim 1, characterized in that not all of the signatures that comprise the first set of signatures, orthogonal to each other, and that each pair of signatures, the contained in the first set of signatures, a low cross-correlation Has. Primary Station ( 100 ) for use in a radio communication system having a random access channel for transmissions from a secondary station according to claims 6 to 10 to the primary station, in which means are provided to receive an access preamble sent by the secondary station, which is associated with a first signature which has been selected from a first set of signatures to determine the first signature to determine from the access preamble which random access channel resource the secondary station wishes to allocate and to send an access acknowledgment which encodes a second signature which is selected from a second set of signatures and indicates whether the requested resource is available, wherein the selection of the first signature provides further information relating to the resource allocation request, characterized in that each signature of the second set a variety of signatures in corresponds to the first sentence. primary Station according to claim 3, characterized in that means are provided are to determine which of a variety of available time offsets the Access preamble was transmitted, the offset being more information related to the request to allocate resources. primary Station according to claim 4, characterized in that means are provided are to receive a rip-off preamble from the secondary Station in response to receiving the access acknowledgment transmit to determine which of the plurality of available time offsets the Rendered competition preamble and to transfer a contraceptive acknowledgment, indicating whether the secondary Station was granted access to the requested resource. Secondary Station ( 110 ) for use in a radio communication system having a random access channel for transmission to a primary station ( 100 ) according to claims 3 to 5, wherein means are provided to request assignment of a random access channel resource by transmission of an access preamble encoded with a first signature selected from a first set of signatures and an access acknowledgment received, encoded with a second signature selected from a second set of signatures and indicating whether the requested resource is available, the selection of the first signature providing further information relating to the resource allocation request, characterized in that each signature of the second set corresponds to a plurality of signatures in the first set. secondary Station according to claim 6, characterized in that the access preamble at transmit one of a plurality of available time slots where the offset is more information related to the request to allocate resources. secondary Station according to claim 7, characterized in that means are provided are to receive an access acknowledgment from the primary station indicating the successful receipt of the access preamble, and in response upon it a rival preamble at one of the multitude to disposal standing time offenses transferred to. secondary Station according to claim 8, characterized in that the use from any of the variety of available time offsets the transmission the preamble before the time leads, where they are transmitted without the offset would. secondary Station according to claim 8 or 9, characterized in that the for the transmission of access preamble and the competition cleanup preamble used time offenses the same ones are. Method for operating a radio communication system with a random access channel for transmissions from a secondary station ( 110 ) to a primary station ( 100 ), the method comprising: the secondary station ( 110 ) requests the assignment ( 202 ) a random access channel resource by transmitting an access preamble encoded with a first signature selected from a first set of signatures; and the primary station ( 100 ) receives the access preamble, determines the first signature and transmits an access acknowledgment ( 204 . 206 ) coded with a second signature, wel is selected from a second set of signatures and indicates whether the requested resource is available, the selection of the first signature providing further information relating to the resource allocation request, characterized in that each signature of the second set is of a plurality of signatures in the first sentence. Method according to claim 11, characterized in that that not all of the signatures that make up the first set of signatures include, are mutually orthogonal, and that each pair of signatures, which are contained in the first set of signatures, a small one Cross correlation has. Method according to claim 11 or 12, characterized that the access preamble at one of a plurality of available time slots becomes and that the primary Station determines its time offset, wherein the time offset of the access preamble transmission further information regarding the request for assignment of resources.